MPI-NAT SEMINAR SERIES: Getting the message: the mechanism of mRNA recruitment to the human ribosome
MPI-NAT SEMINAR SERIES
- Date: Sep 8, 2025
- Time: 10:00 AM - 11:00 AM (Local Time Germany)
- Speaker: Christopher S Fraser
- Department of Milocular and Cellular Biology, UC Davis, USA
- Location: Max-Planck-Institut für Multidisziplinäre Naturwissenschaften (MPI-NAT, Faßberg-Campus)
- Room: Ludwig Prandtl Hall
- Host: Marina Rodnina
- Contact: office.rodnina@mpinat.mpg.de
Translation initiation is a major control point in gene expression, yet the molecular mechanism of mRNA entry into the ribosome remains incompletely understood. A central question is how the mRNA entry channel of the 40S subunit is opened to allow message recruitment. My laboratory addressed this problem by discovering that the initiation factor eIF3j occupies the channel, revealing that recruitment is not passive but requires active displacement of inhibitory factors. These findings established the entry channel as a central regulatory center in initiation.
Using a fully reconstituted human initiation system, real-time fluorescence assays, and cryo-electron microscopy, we have built a mechanistic framework that explains how this barrier is overcome. We find that mRNA recruitment proceeds through distinct kinetic states: an initial rapid sampling step, followed either by accommodation of the message into the channel or by an arrested state in which the message remains bound but poorly engaged for scanning. Importantly, the cap-binding complex eIF4F, through its helicase subunit eIF4A and ATP hydrolysis, remodels the 40S subunit to displace eIF3j and promote mRNA entry. Structured mRNAs are further supported by eIF4E, which stimulates eIF4A activity.
Structural studies have revealed how eIF4F binds to the ribosome near the mRNA exit channel, consistent with an mRNA “slotting” recruitment mechanism. They also showed that a second eIF4A is positioned at the entry channel of the 48S complex, where it likely drives unwinding of mRNA secondary structure during scanning. Finally, I will describe our recent discovery that the tumor suppressor Pdcd4 binds at the entry channel and inhibits this second eIF4A, establishing a regulatory checkpoint. Together, these findings provide a mechanistic framework for how initiation factors and regulators govern selective mRNA recruitment, with implications for gene expression control and disease.
Using a fully reconstituted human initiation system, real-time fluorescence assays, and cryo-electron microscopy, we have built a mechanistic framework that explains how this barrier is overcome. We find that mRNA recruitment proceeds through distinct kinetic states: an initial rapid sampling step, followed either by accommodation of the message into the channel or by an arrested state in which the message remains bound but poorly engaged for scanning. Importantly, the cap-binding complex eIF4F, through its helicase subunit eIF4A and ATP hydrolysis, remodels the 40S subunit to displace eIF3j and promote mRNA entry. Structured mRNAs are further supported by eIF4E, which stimulates eIF4A activity.
Structural studies have revealed how eIF4F binds to the ribosome near the mRNA exit channel, consistent with an mRNA “slotting” recruitment mechanism. They also showed that a second eIF4A is positioned at the entry channel of the 48S complex, where it likely drives unwinding of mRNA secondary structure during scanning. Finally, I will describe our recent discovery that the tumor suppressor Pdcd4 binds at the entry channel and inhibits this second eIF4A, establishing a regulatory checkpoint. Together, these findings provide a mechanistic framework for how initiation factors and regulators govern selective mRNA recruitment, with implications for gene expression control and disease.